JP4485957B2 - Radio resource allocation method and apparatus in multi-standard radio communication system - Google Patents

Description

  The present invention relates to multi-standard wireless communication systems, and more particularly to a method and apparatus for allocating RF resources in a multi-standard communication system.

  With the development of mobile communication systems, more and more communication standards (ie, wireless communication systems) have emerged. For example, GSM, IS-95 and CMDA, 2G to 3G communication belonging to the second generation (2G) communication system. There are GPRS and TSM belonging to the system, TD-SCDMA, W-CDMA and cdma2000 included in the third generation (3G) communication system, and WLAN, which is another popular wireless communication system.

  According to ITU regulations, mobile communication systems having different wireless communication schemes are required to transmit data using carriers in different frequency bands. However, with the rapid development of communication services, various wireless communication schemes appear, that is, different wireless communication schemes may transmit data using different carriers in the same frequency band. Typically, the TSM communication system proposed by the China Wireless Communication Standard group (CWTS) shares the same frequency band as the TD-SCDMA communication system.

  TD-SCDMA is a TDD mode communication system that transmits data using SCDMA (synchronous code division multiple access) technology, whereas TSM is a TD-based communication system based on an existing communication system based on the GSM communication system. -It is designed as a communication system that develops into a communication system based on the SCDMA communication system. As a provisional communication method, the TSM communication method shares the same frequency band as the TD-SCDMA communication method in order to transmit data.

  As communication systems evolve from TSM communication systems to TD-SCDMA communication systems, TSM subscribers and TD-SCDMA subscribers experience constant changes. That is, TSM subscribers occupy a large number at the beginning of development, but as development progresses, TSM subscribers gradually decrease and TD-SCDMA subscribers increase, and at the end of development, TD-SCDMA subscribers increase. While constituting a large number, TSM subscribers will only occupy a small number. Due to significant changes in the configuration of TSM subscribers and TD-SCDMA subscribers, different frequency resources are required, and therefore limited frequency resources need to be dynamically allocated between coexisting wireless communication systems, To achieve reasonable allocation and reuse of RF resources.

  Accordingly, an object of the present invention is a method and apparatus for allocating RF resources in a multi-standard wireless communication system, and dynamically allocating a limited RF resource to a coexisting wireless communication system as required. It is to provide a method and apparatus capable of

  Another object of the present invention is a method and apparatus for allocating RF resources in a multi-standard wireless communication system that is shared by coexisting wireless communication systems in order to improve spectrum utilization in a long development process. It is to provide a method and apparatus capable of statistically configuring resources.

  Another object of the present invention is a method and apparatus for allocating RF resources between multi-standard wireless communication systems, shared by coexisting wireless communication schemes to improve spectrum utilization in the early and late stages of development. It is an object of the present invention to provide a method and apparatus capable of providing an expected configuration for an RF resource.

In order to satisfy the above object, as a proposal of the present invention, a method for allocating RF resources between multi-standard wireless communication systems includes:
(A) detecting a plurality of received signals from the uplink, including a plurality of received signals including information on types of different wireless communication schemes requested to be accessed; and (b) according to the detected information. And allocating wireless RF resources shared by the different communication methods.

In order to achieve the above object, as a proposal of the present invention, an apparatus for allocating RF resources between multi-standard wireless communication systems includes:
A state detection device for detecting a plurality of received signals from the uplink, the state detection device including information on the types of different wireless communication methods requested to be accessed, and the different communication methods according to the detection information A resource allocator for allocating RF resources shared by.

In order to achieve the above object, the wireless communication system proposed in the present invention is:
A plurality of transceivers for transmitting and receiving RF signals;
A plurality of RF processing units for processing the received signals or signals transmitted by the transceiver;
Detecting information contained in received signals from the uplink for different types of wireless communication schemes that are required to be accessed, and allocating RF resources shared by the different communication schemes according to the detection information; A resource allocator.

  The present invention is further described below with reference to the accompanying figures.

  The present invention provides a method and apparatus for dynamically allocating RF resources to wireless communication systems coexisting in a base station according to different requirements of the coexisting wireless communication systems. In the following wireless communication system embodiments in which TSM and TD-SCDMA wireless communication systems coexist, the method and apparatus have different characteristics when applied to the coexisting wireless communication system during different development stages. .

  The description is provided by the present invention for statistical configuration of shared RF resources during development in a communication system in which TSM and TD-SCDMA wireless communication systems coexist with reference to the accompanying drawings. To each of the methods and apparatus provided by the present invention for performing an expected configuration of shared RF resources during the early and late stages of development.

  As shown in FIG. 1, A, B, C, D, E, and Z indicate six cells, which constitute a mobile communication system, cell Z is a central cell, and cells A to E are cells. It is an adjacent cell of Z.

  As shown in FIG. 2, all the cells in FIG. 1 include a base station 10 (ie, Node B) and one or more mobile terminals 20.

  FIG. 3 shows the structure of the cell base station 10 in FIG. As shown in FIG. 3, the base station 10 includes N antennas 30 for transmitting and receiving RF signals, N RF units 40, and one controller 50, where all RF units 40 are It consists of transceiver, modulator and demodulator. The input / output of the transceiver is coupled to the corresponding antenna 30 to receive or transmit an RF signal through the antenna 30 and the output of the transceiver demodulates the received RF signal. In order to do so, it is coupled to the input of the demodulator and the input of the transceiver is coupled to the output of the modulator so as to send a modulated signal for transmission to the antenna 30. Every RF unit 40 has its own RF carrier to transmit data.

  The controller 50 includes a processor 60, an allocator 80, a memory 70, and a system state detector 90, which is coupled to the other inputs and outputs of the transceiver in each of the RF units 40, whereby each RF The processor 60 receives a signal from the unit 40, and at the same time, the processor 60 communicates with the allocator 80, the memory 70, and the system state detector 90. More specifically, the state detector 90 requests access according to the signal from the processor 60. The type of the wireless communication method being used is detected. When used to store information about RF resource allocation in a multi-standard wireless communication system, if the base station selects a method of statistical configuration of RF resources, the memory 70 may be a state detection device over a period of time. It is also used to record the number of access requests to each of the wireless communication schemes detected by 90. The resource allocator 80 follows the number of access requests to each of the different radio communication schemes recorded by the memory in the statistical configuration method, or is stored in the type of radio communication scheme detected by the state detection device 90 and in the memory. According to the information on the RF resource allocation, the RF resources shared by the TSM and TD-SCDMA wireless communication systems are dynamically allocated. The processor 60 then controls and adjusts the RF carrier in the RF unit 40 in accordance with instructions from the resource allocator 80.

  The detailed description given below is made to the statistical construction method and the prediction construction method, respectively, according to different development stages of the TSM and TD-SCDMA communication systems.

[Statistical configuration method]
In general, the development from the TSM communication system to the TD-SCDMA communication system is a long-term process that will continue for several years. In this case, the subscribers of the two wireless communication systems do not change drastically during this process, so the configuration of the RF resources can be performed at intervals, for example, every other month.

  The resource allocator 80 determines the RF carrier in each cell according to the number of requests for accessing each of the TSM radio communication schemes and the number of requests for the TD-SCDMA radio communication scheme recorded by the memory 70 within one interval. The number reassigned and recorded here by the memory 70 is the total traffic load number of each of the two wireless communication schemes over the entire interval. Before the next interval is started, the memory 70 is cleared and records the number of access requests for each of the TSM and TD-SCDMA wireless communication systems detected by the state detector 90 in the next interval.

  Two embodiments are presented to illustrate the statistical configuration method, in which the allocator 80 dynamically allocates RF resources according to the number of access requests for each of the wireless communication schemes.

(Embodiment 1)
If an RF resource needs to be configured after a certain interval, the allocator 80 first accesses the memory 70 and determines the number of access requests for each of the two wireless communication systems detected by the state detection device 90 within that interval. The ratio R between the number of inquiries and the number of access requests to the TSM communication system and the number of access requests to the TD-SCDMA communication system is calculated. Thereafter, assuming that the number of RF carriers in the cell is N, the allocator 80 assigns the number of carriers for the TSM communication scheme as N1 and the number of carriers for the TD-SCDMA communication scheme as N2, where N1 / N2 is calculated as N1 + N2 = N. The allocator 80 assigns several pairs of N1 and N2 (N1 and N2 must be maintained at 1 or more to ensure that the two wireless communication schemes are accessible), and N1 and For every set of N2, N1 / N2 values are obtained and then according to the calculated ratio R, the allocator 80 takes the N1 / N2 value closest to R and takes N RF carriers as two TSMs. And TD-SCDMA wireless communication system.

  For example, the number is 3.4 erlangs (Erl) for the TSM radio communication system, 8.5 erlangs (Erl) for the TD-SCDMA radio communication system, N = 8, and R = 0.4. When two RF carriers are allocated to the TSM radio communication system and six RF carriers are allocated to the TD-SCDMA radio communication system, N1 / N2 = 0.3333 can be obtained. When three RF carriers are allocated to the TSM radio communication system and five RF carriers are allocated to the TD-SCDMA radio communication system, N1 / N2 = 0.6 can be obtained. As described above, allocator 80 must choose the first RF carrier assignment that is closer to R.

(Embodiment 2)
In the first embodiment, the allocator 80 uses the number of access requests to each of the TSM and TD-SCDMA wireless communication schemes in the entire interval in order to calculate the traffic ratio R. However, the most important data is the data from the interval rush hour that is most relevant to the block rate, and thus in the second embodiment, a slight modification to the first embodiment. In other words, instead of the number of requests over the entire interval, only the number of requests from the congestion time of the interval is used to calculate the ratio R. Others are the same as in the first embodiment.

[Prediction configuration method]
In the early stages of development, TD-SCDMA subscribers are considered to be far fewer than TSM subscribers. In this case, if the RF carrier for the TD-SCDMA wireless communication system is still held in each cell, it becomes very inefficient. Embodiment 1 of the predictive configuration method in the present invention is introduced to solve this problem.

(Embodiment 1)
According to the predictive configuration method, all RF carriers in the cell are allocated to the TSM radio communication system, and only one RF carrier is allocated to the TD-SCDMA radio communication system only in the following cases. that is,
(1) When a TD-SCDMA subscriber sends a connection request in a cell,
(2) When a TD-SCDMA subscriber moves from a neighboring cell to the cell and sends a handover request within the cell.

  As in the predictive configuration method shown in FIG. 4, in the cell, when there is no connection from the TD-SCDMA subscriber, all RF carriers are assigned to the TSM wireless communication system (S1). When a TD-SCDMA subscriber in a cell sends a connection or handover request (S10), the base station in the cell first determines whether there is an RF resource available for the TD-SCDMA wireless communication scheme. (S20) If there is an RF resource available for the TD-SCDMA wireless communication system, the RF resource is allocated for the request (S30) and available for the TD-SCDMA wireless communication system. If there is no RF resource, it is determined whether there is an available RF carrier (S40). If there is an available RF carrier, the RF carrier is assigned to the TD-SCDMA wireless communication system (S50). The RF resource corresponding to the RF carrier is then allocated to the request (S60), and if no RF carrier is available, the request is rejected. Is (S70), the request is terminated (S1001).

  When all the communications of the TD-SCDMA wireless communication system are completed in the cell, that is, when the connection of the TD-SCDMA wireless communication system is lost in the cell, the RF carrier occupied by the TD-SCDMA wireless communication system is changed to the TSM wireless. It will be reassigned to the communication method.

  At the end of development, the situation is completely reversed. Almost all subscribers are subscribers of the TD-SCDMA wireless communication system except for a small number of TSM subscribers. In this case, if the RF carrier remains retained for TSM communication in each cell, it can be very inefficient. Embodiment 2 of the predictive configuration method of the present invention is introduced to solve this problem.

Embodiment 2
According to the above predictive configuration method, all RF carriers in a cell are allocated to the TD-SCDMA radio communication system except in the following cases where one RF carrier is allocated to the TSM radio communication system. That is: (1) When a TSM subscriber sends a connection request in a cell,
(2) When the TSM subscriber moves from the neighboring cell to the cell and sends a handover request in the cell.

  When there is no connection from the TSM subscriber in the cell as in the predictive configuration method shown in FIG. 5, all RF carriers are allocated to the TD-SCDMA wireless communication system (S1). When a TSM subscriber in a cell sends a connection or handover request (S100), the base station in the cell first determines whether there are any RF resources available for the TSM wireless communication scheme (S200). If there is an RF resource that can be used in the TSM wireless communication system, the RF resource is allocated to the request (S300), and if there is no RF resource available in the TSM wireless communication system, it can be used. If there is an available RF carrier (S400), and if there is an available RF carrier, the RF carrier is assigned to the TSM wireless communication system (S500), and then the RF resource corresponding to the RF carrier is If there is no RF carrier available, the request is rejected (S700) and the request is terminated (S1). 01).

  When all the communication of the TSM wireless communication system is completed (S1000), that is, when the connection of the TSM wireless communication system is lost in the cell, the RF carrier occupied by the TSM wireless communication system is again transferred to the TD-SCDMA wireless communication system. Will be assigned.

  In fact, we specify most of the RF carriers by the statistical configuration method and retain some carriers for the predictive configuration method in order to adapt to sudden changes in the number of subscribers in different wireless communication schemes. To do.

[Useful use of the present invention]
With respect to the method and apparatus according to the present invention for allocating RF resources in a multi-standard wireless communication system, the resource allocator of the apparatus is configured to use different wireless communication schemes for detecting RF resources shared by coexisting wireless communication schemes by state detection devices. According to the number of access requests for each, it can be allocated in a timely manner, whereby the method and apparatus of the present invention can dynamically allocate limited RF resources for coexisting wireless communication schemes.

  With respect to the method and apparatus according to the present invention for allocating RF resources in a multi-standard wireless communication system, the method and apparatus of the present invention are arranged according to different development stages of the communication system and different traffic requirements ratios, Or a combination thereof, therefore, the method and apparatus can achieve a reasonable configuration of RF resources shared by coexisting wireless communication schemes, thereby limiting the use of limited RF resources. Can be increased.

  Of course, although the present invention has been shown and described according to a preferred embodiment, those skilled in the art will recognize that the RF resource allocation method for the multi-standard wireless communication system provided in the present invention is a communication using a TSM or TD-SCDMA communication scheme. It will be understood that the present invention is not limited to the system but can be applied to a communication system using other wireless communication methods.

  Further, those skilled in the art will appreciate that various improvements can be made to the RF resource allocation method for the multi-standard wireless communication system disclosed in the present invention. Therefore, the scope of the invention to be protected needs to be determined from the claims.

It is a figure which shows the structure of a cellular communication system. It is a figure which shows the structure of each cell of the cellular communication system of FIG. It is a figure which shows the structure of the base station / node of each cell in FIG. 3 is a flowchart of a prediction configuration method 1. It is a flowchart of the prediction structure method 2. FIG.

Claims (36)

(A) detecting a plurality of received signals from the uplink, including a plurality of received signals including information on types of different wireless communication schemes requested to be accessed; and (b) different according to the detection information. A method of assigning radio RF resources in a multi-standard radio communication system comprising allocating radio RF resources shared by a communication scheme ,
The step (b)
(B1) performing statistics on information regarding access requests to each of the different wireless communication schemes at certain set intervals; and
(B2) allocating the RF resource shared by the different wireless communication schemes according to the statistics of the set interval;
The method wherein the information regarding access requests to each of the different wireless communication schemes includes a number of access requests to each of the different wireless communication schemes to calculate a traffic ratio . The method according to claim 1 , wherein in the step (b2), the traffic ratio is realized by calculating a ratio of the number of access requests to each of the different wireless communication schemes. In step (b1), the statistics, the entirety of the predetermined gap, is achieved by performing a statistical of the information about the access request to each of the different wireless communication schemes, claim 1 or claim 2 The method described in 1. Wherein in step (b1), the statistics are within crowded time of the setting interval, the is achieved by carrying out the statistical of the information about the access request to each of the different radio communication systems, according to claim 1, wherein Item 3. The method according to Item 2 . The step (b)
(B2) determining whether there is an RF resource available for a request to access the different wireless communication scheme; and (b3) if there is an RF resource available for the request, the request The method according to any of claims 1 to 4 , further comprising allocating the available RF resources to the. The step (b)
(B1) preallocating the RF resource to a specific communication method;
(B2) if the different wireless communication scheme is not the specific communication scheme, determine whether there is an RF resource available for requesting access to the different wireless communication scheme; and (b3) 5. The method according to any of claims 1 to 4 , further comprising allocating the available RF resource for the request if there is an RF resource available for the request. The steps (b2) and (b3)
The method according to claim 5 or 6 , wherein the method is executed on condition that a subscriber sends a connection request to access the different wireless communication scheme. Steps (b2) and (b3)
The method according to claim 5 or 6 , wherein the method is executed on condition that a subscriber performing a cell handover sends a handover request to access the different radio communication scheme. The step (b3)
(I) if there are no RF resources available for the access request to the wireless communication scheme, determine if there is an RF carrier available for the request; and (ii) 9. The method of claims 5-8 , further comprising assigning the available RF carrier to the wireless communication scheme and assigning a corresponding RF resource to the request if there is an RF carrier available for use . The method according to any one . Said step (ii) comprises
The method according to claim 9 , further comprising releasing the RF carrier assigned to the request when communication employing the wireless communication scheme is terminated. Said step (ii) comprises
The method of claim 9 or claim 10 , further comprising rejecting the request if no RF carrier is available for the request. The wireless communication method, IS-95, CDMA, GSM , TSM, GPRS, TD-SCDMA, W-CDMA cdma2000, and at least two of the WLAN, according to any one of claims 1 to 11 the method of. An apparatus for allocating RF resources in a multi-standard wireless communication system,
A state detection device for detecting a plurality of received signals from the uplink, the state detection device including information on types of different wireless communication schemes requested to be accessed;
A resource allocator for allocating the RF resource shared by the different communication methods according to the detection information ,
The resource allocator allocates the RF resources according to statistics of information regarding access requests to each of the different communication methods within a set interval;
The apparatus, wherein the information regarding access requests to each of the different communication schemes includes a number of access requests to each of the different communication schemes to calculate a traffic ratio . 14. The apparatus of claim 13 , wherein the resource allocator implements the traffic ratio by calculating a ratio of access requests to each of the different wireless communication schemes. 15. An apparatus according to claim 13 or claim 14 , wherein the statistics are achieved by performing statistics of the information regarding access requests to each of the different wireless communication schemes throughout the set interval. The apparatus according to claim 13 or 14 , wherein the statistics are achieved by performing statistics of the information regarding access requests to each of the different wireless communication schemes within a congestion time of the set interval. The RF resource allocation performed by the resource allocator is:
(B) determining whether there is an RF resource available for a request to access the different wireless communication scheme; and (c) if there is an RF resource available for the request, the request 17. An apparatus according to any of claims 13 to 16, comprising allocating the available RF resources for a. The RF resource allocation performed by the resource allocator is:
(A) pre-allocating the RF resource to a specific communication method;
(B) if the different radio communication scheme is not a specific communication scheme, determine whether there are any RF resources available for requesting access to the different radio communication scheme; and (c) for the request 17. An apparatus according to any of claims 13 to 16, comprising assigning the available RF resource to the request if there is an available RF resource. Steps (b) and (c)
19. The apparatus according to claim 17 or 18 , wherein the apparatus is executed on condition that a subscriber sends a connection request to access the different wireless communication scheme. Steps (b) and (c)
19. The apparatus according to claim 17 or 18 , wherein the apparatus is executed on condition that a subscriber performing a cell handover sends a handover request to access the different radio communication scheme. The RF resource allocation performed by the resource allocator is:
If there is no RF resource available for the request, determine if there is an RF carrier available for the access request to the different wireless communication scheme, and available for the request 21. The method according to any one of claims 17 to 20, comprising assigning the available RF carrier to the different wireless communication scheme, if there is an RF carrier, and allocating the corresponding RF resource to the request. Equipment. The RF resource allocation performed by the resource allocator is:
The apparatus of claim 21 , comprising: releasing the RF carrier assigned to the request when communication employing the different wireless communication scheme is terminated. The RF resource allocation performed by the resource allocator is:
23. The apparatus of claim 21 or claim 22 , comprising rejecting the request if no RF carrier is available for the request. 24. The any one of claims 13 to 23, wherein the different wireless communication schemes include at least two of IS-95, CDMA, GSM, TSM, GPRS, TD-SCDMA, W-CDMA, cdma2000, and WLAN . The device described in 1. A plurality of transceivers for transmitting and receiving RF signals;
A plurality of RF processing units for processing the received signals or signals transmitted by the transceiver;
An RF resource allocator that detects information included in a received signal from an uplink regarding the type of the different wireless communication scheme for which access is requested, and is shared by the different communication schemes according to the detected information An RF resource allocator for allocating RF resources ;
The RF resource allocator allocates the RF resource according to statistics of information regarding access requests to each of the different wireless communication methods within a set interval;
The wireless communication system, wherein the information regarding access requests to each of the different wireless communication schemes includes the number of access requests to each of the different wireless communication schemes to calculate a traffic ratio . 26. The system of claim 25 , wherein the RF resource allocator implements the traffic ratio by calculating a ratio of access requests to each of the different wireless communication schemes. 27. A system according to claim 25 or claim 26 , wherein the statistics are achieved by performing statistics of the information regarding access requests to each of the different wireless communication schemes throughout the set interval. 27. A system according to claim 25 or claim 26 , wherein the statistics are achieved by performing statistics of the information regarding access requests to each of the different wireless communication schemes within a congestion time of the set interval. The RF resource allocation performed by the RF resource allocator is:
(B) determining whether there is an RF resource available for a request to access the different wireless communication scheme; and (c) if there is an RF resource available for the request, the request 30. A system according to any of claims 25 to 28, comprising allocating the available RF resources to a. The RF resource allocation performed by the RF resource allocator is:
(A) pre-allocating the RF resource to a specific communication method;
(B) determining whether there is an RF resource available for a request to access the different radio communication scheme if the different radio communication scheme is not a specific communication scheme; and (c) for the request 29. A system according to any of claims 25 to 28, comprising assigning the available RF resource to the request if there is an available RF resource. Steps (b) and (c)
31. The system according to claim 29 or 30 , wherein the system is executed on condition that a subscriber sends a connection request to access the different wireless communication scheme. Steps (b) and (c)
31. The system according to claim 29 or 30 , wherein the system is executed on condition that a subscriber performing a cell handover sends a handover request to access the different radio communication scheme. The RF resource allocation performed by the RF resource allocator is
If there is no RF resource available for the request, determine if there is an RF carrier available for the access request to the different wireless communication scheme, and available for the request 33. A method according to any of claims 29 to 32, comprising assigning the available RF carrier to the different wireless communication scheme, if there is an RF carrier, and allocating the corresponding RF resource to the request. System. The RF resource allocation performed by the RF resource allocator is:
34. The system of claim 33 , wherein the RF carrier assigned to the request is released when communication utilizing the different wireless communication scheme is terminated. The RF resource allocation performed by the RF resource allocator is:
35. A system according to claim 33 or claim 34 , wherein the request is rejected if no RF carrier is available for the request. 36. The any one of claims 25 to 35, wherein the different wireless communication schemes include at least two of IS-95, CDMA, GSM, TSM, GPRS, TD-SCDMA, W-CDMA, cdma2000, and WLAN . The system described in.

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